php_world

This module extends Deno world with PHP, by running commandline PHP interpreter in the background, or by connecting to a PHP-FPM service.

There are several possible reasons to use php_world:

  1. If you have a large PHP application, and you wish to convert it to Javascript/Typescript, but it’s impossible to achieve at once. In this case php_world allows you to start writing new code in Javascript/Typescript, and convert each part of the application later, as desired.
  2. If you want to benefit from PHP functionality or third-party PHP libraries/SDKs or database drivers.

Requirements

PHP-CLI or PHP-FPM must be installed on your system.

Limitations

  1. Unfortunately it’s impossible to automatically garbage-collect PHP object handles, so delete must be used explicitly (see below). However there are helper methods.

Examples

Usage

import {g, c} from 'https://deno.land/x/php_world/mod.ts';
// ...
// and at last, terminate the interpreter
await g.exit();

Run the script as follows:

deno run --unstable --allow-read --allow-write --allow-net --allow-run=php main.ts

By default php_world will execute the php CLI command. If in your system PHP appears under different name, you need to set it before accessing php_world interfaces.

import {g, c, settings} from 'https://deno.land/x/php_world/mod.ts';

settings.php_cli_name = 'php7.4';
// now access php_world interfaces
// ...
// and at last, terminate the interpreter
await g.exit();

There are several configurable settings:

  1. settings.php_cli_name - PHP-CLI command name (default php).
  2. settings.unix_socket_name - php_world uses socket channel to communicate with the remote interpreter. By default it uses random (free) TCP port. On non-Windows systems you can use a unix-domain socket. Set settings.unix_socket_name to full path of socket node file, where it will be created.
  3. settings.stdout - allows to redirect PHP process echo output (see below).
  4. settings.php_fpm.listen - If set, php_world will use PHP-FPM service, not CLI. Set this to what appears in your PHP-FPM pool configuration file (see line that contains listen = ...).
  5. settings.php_fpm.keep_alive_timeout - Connections to PHP-FPM service will be reused for this number of milliseconds (deno script may not exit while there’re idle connections - call php.close_idle() to close them).

Interface

php_world library exports the following symbols:

  1. PhpInterpreter - constructor for new PHP interpreter to run in the background.
  2. php - default interpreter (created with new PhpInterpreter).
  3. g - the same as php.g. Contains all the PHP functions, global constants and variables.
  4. c - the same as php.c. Contains classes.
  5. settings - the same as php.settings. Allows to modify interpreter settings.
  6. InterpreterError - class for exceptions propagated from PHP.
  7. InterpreterExitError - this error is thrown in case PHP interpreter exits or crashes.
  8. ResponseWithCookies - type that php.get_response() returns.

Calling functions

Each function becomes async, because calling it involves IPC (interprocess communication) with the background PHP interpreter.

import {g} from 'https://deno.land/x/php_world/mod.ts';
const {eval: php_eval, phpversion, class_exists, exit} = g;

console.log(await phpversion());
await php_eval('class Hello {}');
console.log(await class_exists('Hello'));
await exit();

At the end of Deno script, it’s nice to call exit(). This function terminates the interpreter, and frees all the resources. After this function called, the php_world can be used again, and a new instance of the interpreter will be spawned. It’s OK to call exit() several times. If settings.stdout is set to piped (see below), calling exit() may be necessary to let Deno script exit naturally at it’s end, and not awaiting for PHP output.

If function’s result is not awaited-for, the function will work in the background, and if it throws exception, this exception will come out on next operation awaiting. After exception occures, all further operations in current microtask iteration will be skipped (see below).

Global constants

Constant’s value must be awaited-for.

import {g, c} from 'https://deno.land/x/php_world/mod.ts';

console.log(await g.PHP_VERSION);
console.log((await g.FAKE) === undefined); // unexisting constants have "undefined" value

Global variables

Like constants, variables are present in the g namespace, but their names must begin with a ‘$’.

Variable’s value must be awaited-for. But setting new value returns immediately (and doesn’t imply synchronous operations - the value will be set in the background, and there’s no result that we need to await for).

import {g, c} from 'https://deno.land/x/php_world/mod.ts';

console.log((await g.$ten) === undefined); // unexisting variables have "undefined" value
g.$ten = 10;
console.log(await g.$ten);

Individual keys can be accessed.

import {g, c} from 'https://deno.land/x/php_world/mod.ts';

g.$_SERVER['hello']['world'] = true;
console.log(await g.$_SERVER['hello']);

It’s possible to unset a key.

import {g, c} from 'https://deno.land/x/php_world/mod.ts';

console.log(await g.$_SERVER['argc']); // likely to print '1'
delete g.$_SERVER['argc'];
console.log((await g.$_SERVER['argc']) === undefined); // prints "true"

Classes

Classes are present in the c namespace.

Class-static constants

import {g, c} from 'https://deno.land/x/php_world/mod.ts';
const {eval: php_eval} = g;
const {Value} = c;

await php_eval('class Value {const TEN = 10;}');
console.log((await Value.NINE) === undefined); // unexisting constants have "undefined" value
console.log(await Value.TEN);

Class-static variables

import {g, c} from 'https://deno.land/x/php_world/mod.ts';
const {eval: php_eval} = g;
const {Value} = c;

await php_eval('class Value {static $ten = 10;}');
console.log((await Value.$nine) === undefined); // unexisting variables have "undefined" value
console.log(await Value.$ten);

Class-static methods

import {g, c} from 'https://deno.land/x/php_world/mod.ts';
const {eval: php_eval} = g;
const {Value} = c;

await php_eval
(	`	class Value
        {	static function get_ten()
            {	return 10;
            }
        }
    `
);
console.log(await Value.get_ten());

Class construction and destruction

To create a class instance, call the constructor, and await the result. It returns handler to remote PHP object.

import {g, c} from 'https://deno.land/x/php_world/mod.ts';
const {eval: php_eval} = g;
const {Value} = c;

await php_eval('class Value {}');
let value = await new Value;

Each instance created with new, must be destroyed with delete. Special property this must be deleted (because just delete obj is invalid syntax in strict mode).

delete value.this;

For debugging purposes it’s possible to query number of currently allocated objects. This number must reach 0 at the end of the script.

import {g, c, php} from 'https://deno.land/x/php_world/mod.ts';

console.log(await php.n_objects()); // prints 0
let obj = await new c.Exception('Test');
console.log(await php.n_objects()); // prints 1
delete obj.this;
console.log(await php.n_objects()); // prints 0

To help you free memory, there’s 2 helper functions:

  1. php.push_frame() - All objects allocated after this call, can be freed at once.
  2. php.pop_frame() - Free at once all the objects allocated after last php.push_frame() call.
import {g, c, php} from 'https://deno.land/x/php_world/mod.ts';

php.push_frame();
try
{	let obj = await new c.Exception('Test');
    console.log(await php.n_objects()); // prints 1
}
finally
{	php.pop_frame();
    console.log(await php.n_objects()); // prints 0
}

Instance variables

import {g, c} from 'https://deno.land/x/php_world/mod.ts';
const {eval: php_eval} = g;
const {Value} = c;

await php_eval('class Value {public $ten;}');
let value = await new Value;
value.ten = 10;
console.log(await value.ten);
delete value.this;

Instance methods

import {g, c} from 'https://deno.land/x/php_world/mod.ts';
const {eval: php_eval} = g;
const {Value} = c;

await php_eval
(	`	class Value
        {	public $var;

            function get_twice_var()
            {	return $this->var * 2;
            }
        }
    `
);
let value = await new Value;
value.var = 10;
console.log(await value.get_twice_var());
delete value.this;

Objects returned from functions

When a function is called, and returned a value, this value is JSON-serialized on PHP side, and JSON-parsed in the Deno world. Objects returned from functions are dumb default objects, without methods.

However it’s possible to get object handler as in example with instance construction. To do so need to get special property called this from the object, before awaiting for the result.

import {g, c} from 'https://deno.land/x/php_world/mod.ts';

await g.eval
(	`	function get_ex($msg)
        {	return new Exception($msg);
        }
    `
);

let ex = await g.get_ex('The message').this;
console.log(await ex.getMessage()); // prints 'The message'
delete ex.this;

At last, the object must be deleted. This doesn’t necessarily destroys the object on PHP side, but it stops holding the handler to the object.

Get variables as objects

In the same fashion, it’s possible to get an object-handler to a variable.

import {g, c} from 'https://deno.land/x/php_world/mod.ts';

await g.eval
(	`	function init()
        {	global $e;
            $e = new Exception('The message');
        }
    `
);
await g.init();

let ex = await g.$e.this;
console.log(await ex.getMessage()); // prints 'The message'
delete ex.this;

In this example, i use function init() to create a global variable. Just setting a variable inside eval() doesn’t make it global.

Objects behavior

Remote PHP objects are represented in Deno as opaque Proxy objects, and they don’t feel like real Typescript objects. Most of magic behavior is missing. For example they don’t convert to strings automatically (because toString() magic method is synchronous). Only the following object features work:

  1. Getting, setting and deleting properties.
  2. instanceof operator.
  3. Async iterators.

Example:

import {g, c} from 'https://deno.land/x/php_world/mod.ts';

let obj = await new c.ArrayObject(['a', 'b', 'c']);
console.log(obj instanceof c.ArrayObject); // prints "true"
for await (let item of obj)
{	console.log(item);
}
delete obj.this;

Namespaces

import {g, c} from 'https://deno.land/x/php_world/mod.ts';

await g.eval
(	`	namespace MainNs;

        function get_twice($value)
        {	return $value * 2;
        }

        class Value
        {	public $var;

            function get_triple_var()
            {	return $this->var * 3;
            }
        }
    `
);

console.log(await g.MainNs.get_twice(10));

let value = await new c.MainNs.Value;
value.var = 10;
console.log(await value.get_triple_var());
delete value.this;

Exceptions

PHP exceptions are propagated to Deno as instances of InterpreterError class.

import {g, c, InterpreterError} from 'https://deno.land/x/php_world/mod.ts';

await g.eval
(	`	function failure($msg)
        {	throw new Exception($msg);
        }
    `
);

try
{	await g.failure('Test');
}
catch (e)
{	console.log(e instanceof InterpreterError);
    console.log(e.message);
}

InterpreterError has the following fields: message, fileName, lineNumber, trace (string).

If a function throws exception, and you don’t await for the result, it’s error will be returned to the next awaited operation within current microtask iteration.

import {g, c, php} from 'https://deno.land/x/php_world/mod.ts';

await g.eval
(	`	function failure($msg)
        {	global $n;
            $n++;
            throw new Exception($msg);
        }
    `
);

g.failure('Test 1'); // $n gets the value of 1
g.failure('Test 2'); // this will no be executed, so $n will remain 1
g.failure('Test 3'); // not executed
try
{	// await for anything will throw exception
    // we can use php.ready() to just await for all pending operations
    await php.ready();
}
catch (e)
{	console.log(e.message); // prints 'Test 1'
}
console.log(await g.$n); // prints 1

But if you don’t await any other php_world operation within the current microtask iteration, the exception will be lost.

import {g, c, php} from 'https://deno.land/x/php_world/mod.ts';

await g.eval
(	`	function failure($msg)
        {	global $n;
            $n++;
            throw new Exception($msg);
        }
    `
);

g.failure('Test 1'); // $n gets the value of 1
queueMicrotask
(	async () =>
    {	g.failure('Test 2'); // $n gets the value of 2
        g.failure('Test 3'); // this will no be executed, so $n remains 2
        try
        {	await php.ready(); // throws error 'Test 2'
        }
        catch (e)
        {	console.log(e.message); // prints 'Test 2'
        }
        console.log(await g.$n); // prints 2
    }
);

If PHP interpreter exits (not as result of calling g.exit()), InterpreterExitError exception is thrown.

import {g, InterpreterExitError} from 'https://deno.land/x/php_world/mod.ts';

try
{	await g.eval('exit(100);');
}
catch (e)
{	if (e instanceof InterpreterExitError)
    {	console.log(`PHP exited with code ${e.code}`);
    }
}

The InterpreterExitError class has the following fields: message, code (process exit status code).

Dealing with PHP echo output

There’s setting that provides control on how PHP output is processed: settings.stdout.

stdout: 'inherit'|'piped'|'null'|number = 'inherit'

It’s default value is inherit. For PHP-CLI this value means to pass PHP output to Deno. So g.echo("msg\n") works like console.log("msg").

As usual, it’s possible to use PHP output buffering to catch the output.

import {g} from 'https://deno.land/x/php_world/mod.ts';

g.ob_start();
g.echo("A");
g.echo("B");
g.echo("C");
let output = await g.ob_get_clean();
console.log(output); // prints "ABC"

await g.exit();

But this is not good for large outputs, because the whole output will be stored in RAM.

Setting settings.stdout to piped allows to catch PHP output. Initially the output will be passed to Deno, as in the inherit case, but you’ll be able to call php.get_stdout_reader() to get Deno.Reader object from which the output can be read. To stop reading the output from that reader, and to redirect it back to Deno.stdout, call php.drop_stdout_reader(). This will cause the reader stream to end (EOF).

import {php, settings} from 'https://deno.land/x/php_world/mod.ts';

settings.stdout = 'piped';

let stdout = await php.get_stdout_reader();
php.g.echo("*".repeat(10)); // no await
php.g.echo("."); // queue another function call
php.drop_stdout_reader(); // reader stream will end here

let data = new TextDecoder().decode(await Deno.readAll(stdout));
console.log(data == "*".repeat(10)+"."); // prints "true"

await g.exit();

If settings.stdout is set to something other that piped, calling g.exit() at the end of script is not required, but in case of piped not calling it may cause Deno script not exiting at the end, because the task that reads from PHP STDOUT may not know that there’s no more output expected.

Another options for settings.stdout are null (to ignore the output), and a numeric file descriptor (rid) of an opened file/stream.

For PHP-FPM settings.stdout == inherit has special meaning. It allows to get FastCGI response in format similar to what fetch() returns, and read echo output there. Headers will also be available on the response. To get the response call php.get_response() (see below).

Running several PHP interpreters in parallel

import {g, c, PhpInterpreter} from 'https://deno.land/x/php_world/mod.ts';

let int_1 = new PhpInterpreter;
let int_2 = new PhpInterpreter;

let pid_0 = await g.posix_getpid();
let pid_1 = await int_1.g.posix_getpid();
let pid_2 = await int_2.g.posix_getpid();

console.log(`${pid_0}, <span class="katex"><span class="katex-mathml"><math xmlns="http://www.w3.org/1998/Math/MathML"><semantics><mrow><mrow><mi>p</mi><mi>i</mi><msub><mi>d</mi><mn>1</mn></msub></mrow><mo separator="true">,</mo></mrow><annotation encoding="application/x-tex">{pid_1}, </annotation></semantics></math></span><span class="katex-html" aria-hidden="true"><span class="base"><span class="strut" style="height:0.8889em;vertical-align:-0.1944em;"></span><span class="mord"><span class="mord mathnormal">p</span><span class="mord mathnormal">i</span><span class="mord"><span class="mord mathnormal">d</span><span class="msupsub"><span class="vlist-t vlist-t2"><span class="vlist-r"><span class="vlist" style="height:0.3011em;"><span style="top:-2.55em;margin-left:0em;margin-right:0.05em;"><span class="pstrut" style="height:2.7em;"></span><span class="sizing reset-size6 size3 mtight"><span class="mord mtight">1</span></span></span></span><span class="vlist-s">​</span></span><span class="vlist-r"><span class="vlist" style="height:0.15em;"><span></span></span></span></span></span></span></span><span class="mpunct">,</span></span></span></span>{pid_2}`);

await g.exit();
await int_1.g.exit();
await int_2.g.exit();

Limitations of PHP-CLI

Using PHP-CLI backend is simple, but there are disadvantages.

If some PHP script file declares a function, or some other kind of object, such file cannot be included (or required) multiple times. PHP complains on “Cannot redeclare function”. Practically this means that to execute the same script multiple times, new PHP interpreters must be spawned. Respawning process is slow, and you will not benefit from opcache.

However, it’s possible to reorganize the application in such a way, that script files you run directly don’t declare objects, but call require_once() for files that do declare them.

Another disadvantage is that functions like header() and setcookie() do nothing in PHP-CLI.

Using PHP-FPM

To use PHP-FPM backend (that must be installed on your system), set settings.php_fpm.listen to PHP-FPM service address. You can find it in your PHP-FPM pool configuration file.

To get started you can create a new pool file like this (substitute username with the user from which you run your deno script):

[username]
user = username
group = username
listen = [::1]:8989

pm = dynamic
pm.max_children = 5
pm.start_servers = 2
pm.min_spare_servers = 1
pm.max_spare_servers = 3
import {g, c} from 'https://deno.land/x/php_world/mod.ts';

settings.php_fpm.listen = '[::1]:8989';
console.log(await g.php_sapi_name());
await g.exit(); // in case of PHP-FPM, g.exit() doesn't actually call exit() on PHP side, but it terminates a FCGI request
php.close_idle(); // close idle connection to PHP-FPM (otherwise deno script will not exit immediately)

Common problems:

  1. If using unix-domain socket for PHP-FPM service, the deno script must have access to it (listen.owner = username and/or listen.group = username).
  2. If using unix-domain socket for communication with PHP world (settings.unix_socket_name), the PHP interpreter must have access to this socket (user = username and/or group = username).

If settings.stdout is set to inherit (default value), echo output, together with headers set with header() or setcookie() can be taken as Response object.

import {g, c} from 'https://deno.land/x/php_world/mod.ts';

settings.php_fpm.listen = '[::1]:8989';
php.g.echo(`Hello`);
php.g.exit(); // don't await, since it will destroy the response object
let response = await php.get_response();
console.log(await response.text()); // prints "Hello"
await php.ready(); // await exit() completion
php.close_idle();

The response is returned as soon as it’s ready - usually after first echo from the remote PHP script, and maybe after a few more echoes, or at the end of the script (when php.g.exit() called). The response contains headers and body reader, that will read everything echoed from the script. The returned object is of class ResponseWithCookies. This class extends built-in Response (that fetch() returns) by adding cookies property, that contains all Set-Cookie headers. Also response.body object extends regular ReadableStream<Uint8Array> by adding Deno.Reader implementation.

If you call php.get_response(), you’re responsible to read the body to the end, to free resources. After php.g.exit() awaited, the php.get_response() throws error.

How fast is deno_world?

deno_world spawns a background PHP process, and uses it to execute PHP operations. Every operation, like function call, or getting or setting a variable, sends requests to the PHP process and awaits for responses.

First of all, spawning takes time, but it happens once (or several times if your application calls g.exet() to terminate the interpreter, and then uses the interpreter again). Then every request to execute an operation, not only executes it, but implies many other operations.

What price you pay depends on operation weight. Executing many lightweight operations implies much overhead. And vise versa, if calling PHP functions that do a lot of work, the commission will be negligible.

Understanding this, lets measure the overhead of average deno_world API call.

How much time takes to call the following function in PHP?

function dec()
{	global $n;
    return $n--;
}

Let’s use this time as a measuring unit, and measure how slower is deno_world over native PHP.

import {g} from 'https://deno.land/x/php_world/mod.ts';

await g.eval
(	`	function dec()
        {	global $n;
            return $n--;
        }

        function php_measure_time_per_million_ops(int $bench_times)
        {	global $n;
         <span class="katex"><span class="katex-mathml"><math xmlns="http://www.w3.org/1998/Math/MathML"><semantics><mrow><mi>n</mi><mo>=</mo></mrow><annotation encoding="application/x-tex">n = </annotation></semantics></math></span><span class="katex-html" aria-hidden="true"><span class="base"><span class="strut" style="height:0.4306em;"></span><span class="mord mathnormal">n</span><span class="mspace" style="margin-right:0.2778em;"></span><span class="mrel">=</span></span></span></span>bench_times;
            $start_time = microtime(true);
            while (dec());
            return (microtime(true) - <span class="katex"><span class="katex-mathml"><math xmlns="http://www.w3.org/1998/Math/MathML"><semantics><mrow><mi>s</mi><mi>t</mi><mi>a</mi><mi>r</mi><msub><mi>t</mi><mi>t</mi></msub><mi>i</mi><mi>m</mi><mi>e</mi><mo stretchy="false">)</mo><mo>∗</mo><msub><mn>1</mn><mn>0</mn></msub><mn>0</mn><msub><mn>0</mn><mn>0</mn></msub><mn>00</mn><mi mathvariant="normal">/</mi></mrow><annotation encoding="application/x-tex">start_time) * 1_000_000 / </annotation></semantics></math></span><span class="katex-html" aria-hidden="true"><span class="base"><span class="strut" style="height:1em;vertical-align:-0.25em;"></span><span class="mord mathnormal">s</span><span class="mord mathnormal">t</span><span class="mord mathnormal">a</span><span class="mord mathnormal" style="margin-right:0.02778em;">r</span><span class="mord"><span class="mord mathnormal">t</span><span class="msupsub"><span class="vlist-t vlist-t2"><span class="vlist-r"><span class="vlist" style="height:0.2806em;"><span style="top:-2.55em;margin-left:0em;margin-right:0.05em;"><span class="pstrut" style="height:2.7em;"></span><span class="sizing reset-size6 size3 mtight"><span class="mord mathnormal mtight">t</span></span></span></span><span class="vlist-s">​</span></span><span class="vlist-r"><span class="vlist" style="height:0.15em;"><span></span></span></span></span></span></span><span class="mord mathnormal">im</span><span class="mord mathnormal">e</span><span class="mclose">)</span><span class="mspace" style="margin-right:0.2222em;"></span><span class="mbin">∗</span><span class="mspace" style="margin-right:0.2222em;"></span></span><span class="base"><span class="strut" style="height:1em;vertical-align:-0.25em;"></span><span class="mord"><span class="mord">1</span><span class="msupsub"><span class="vlist-t vlist-t2"><span class="vlist-r"><span class="vlist" style="height:0.3011em;"><span style="top:-2.55em;margin-left:0em;margin-right:0.05em;"><span class="pstrut" style="height:2.7em;"></span><span class="sizing reset-size6 size3 mtight"><span class="mord mtight">0</span></span></span></span><span class="vlist-s">​</span></span><span class="vlist-r"><span class="vlist" style="height:0.15em;"><span></span></span></span></span></span></span><span class="mord">0</span><span class="mord"><span class="mord">0</span><span class="msupsub"><span class="vlist-t vlist-t2"><span class="vlist-r"><span class="vlist" style="height:0.3011em;"><span style="top:-2.55em;margin-left:0em;margin-right:0.05em;"><span class="pstrut" style="height:2.7em;"></span><span class="sizing reset-size6 size3 mtight"><span class="mord mtight">0</span></span></span></span><span class="vlist-s">​</span></span><span class="vlist-r"><span class="vlist" style="height:0.15em;"><span></span></span></span></span></span></span><span class="mord">00/</span></span></span></span>bench_times;
        }
    `
);

let {php_measure_time_per_million_ops, dec} = g;

async function deno_measure_time_per_million_ops(bench_times: number)
{	g.$n = bench_times;
    let start_time = Date.now() / 1000;
    while (await dec());
    return (Date.now()/1000 - start_time) * 1_000_000 / bench_times;
}

let php_native_time = await php_measure_time_per_million_ops(10_000_000);
console.log(`PHP native per million ops: ${php_native_time} sec`);

let api_time = await deno_measure_time_per_million_ops(100_000);
console.log(`API per million ops: <span class="katex"><span class="katex-mathml"><math xmlns="http://www.w3.org/1998/Math/MathML"><semantics><mrow><mrow><mi>a</mi><mi>p</mi><msub><mi>i</mi><mi>t</mi></msub><mi>i</mi><mi>m</mi><mi>e</mi></mrow><mi>s</mi><mi>e</mi><mi>c</mi><mo stretchy="false">(</mo></mrow><annotation encoding="application/x-tex">{api_time} sec (</annotation></semantics></math></span><span class="katex-html" aria-hidden="true"><span class="base"><span class="strut" style="height:1em;vertical-align:-0.25em;"></span><span class="mord"><span class="mord mathnormal">a</span><span class="mord mathnormal">p</span><span class="mord"><span class="mord mathnormal">i</span><span class="msupsub"><span class="vlist-t vlist-t2"><span class="vlist-r"><span class="vlist" style="height:0.2806em;"><span style="top:-2.55em;margin-left:0em;margin-right:0.05em;"><span class="pstrut" style="height:2.7em;"></span><span class="sizing reset-size6 size3 mtight"><span class="mord mathnormal mtight">t</span></span></span></span><span class="vlist-s">​</span></span><span class="vlist-r"><span class="vlist" style="height:0.15em;"><span></span></span></span></span></span></span><span class="mord mathnormal">im</span><span class="mord mathnormal">e</span></span><span class="mord mathnormal">sec</span><span class="mopen">(</span></span></span></span>{Math.round(api_time/php_native_time)} times slower)`);

On my computer i get the following result:

PHP native per million ops: 0.6503312110900878 sec
API per million ops: 67.59000062942505 sec (104 times slower)

This is for the most elementary operation that we can measure. What if this operation would be heavier?

function dec()
{	global <span class="katex"><span class="katex-mathml"><math xmlns="http://www.w3.org/1998/Math/MathML"><semantics><mrow><mi>n</mi><mo separator="true">,</mo></mrow><annotation encoding="application/x-tex">n, </annotation></semantics></math></span><span class="katex-html" aria-hidden="true"><span class="base"><span class="strut" style="height:0.625em;vertical-align:-0.1944em;"></span><span class="mord mathnormal">n</span><span class="mpunct">,</span></span></span></span>v;
 <span class="katex"><span class="katex-mathml"><math xmlns="http://www.w3.org/1998/Math/MathML"><semantics><mrow><mi>v</mi><mo>=</mo><mo stretchy="false">!</mo></mrow><annotation encoding="application/x-tex">v = !</annotation></semantics></math></span><span class="katex-html" aria-hidden="true"><span class="base"><span class="strut" style="height:0.4306em;"></span><span class="mord mathnormal" style="margin-right:0.03588em;">v</span><span class="mspace" style="margin-right:0.2778em;"></span><span class="mrel">=</span></span><span class="base"><span class="strut" style="height:0.6944em;"></span><span class="mclose">!</span></span></span></span>v ? str_repeat('-', 256) : substr(base64_encode($v), 0, 256);
    return $n--;
}

This benchmark takes more time, so i reduce the number of tests to 1_000_000 for PHP-native, and to 100_000 for API. The results on my computer are these:

PHP native per million ops: 2.2854011058807373 sec
API per million ops: 72.03999996185303 sec (32 times slower)

And for a some slower operation?

function dec()
{	global <span class="katex"><span class="katex-mathml"><math xmlns="http://www.w3.org/1998/Math/MathML"><semantics><mrow><mi>n</mi><mo separator="true">,</mo></mrow><annotation encoding="application/x-tex">n, </annotation></semantics></math></span><span class="katex-html" aria-hidden="true"><span class="base"><span class="strut" style="height:0.625em;vertical-align:-0.1944em;"></span><span class="mord mathnormal">n</span><span class="mpunct">,</span></span></span></span>v;
 <span class="katex"><span class="katex-mathml"><math xmlns="http://www.w3.org/1998/Math/MathML"><semantics><mrow><mi>v</mi><mo>=</mo><mo stretchy="false">!</mo></mrow><annotation encoding="application/x-tex">v = !</annotation></semantics></math></span><span class="katex-html" aria-hidden="true"><span class="base"><span class="strut" style="height:0.4306em;"></span><span class="mord mathnormal" style="margin-right:0.03588em;">v</span><span class="mspace" style="margin-right:0.2778em;"></span><span class="mrel">=</span></span><span class="base"><span class="strut" style="height:0.6944em;"></span><span class="mclose">!</span></span></span></span>v ? str_repeat('-', 25600) : substr(base64_encode($v), 0, 25600);
    return $n--;
}

Results:

PHP native per million ops: 41.54288053512573 sec
API per million ops: 118.94999980926514 sec (3 times slower)